RU2144706C1 - Method for circulation cooling of tank holding burnt-out combustible elements for transport and/or storage of combustible elements - Google Patents

Abstract

FIELD: transport and/or storage of combustible elements. SUBSTANCE: cooling water is supplied from water reservoir to tank through circulation cooling device. Vacuum is created within tank and circulation cooling device by means of gas conveying pump unit and steam formed within tank is continuously discharged to at least one condenser wherein it is condensed. EFFECT: high-speed and effective cooling of tank using simple and low-cost means. 3 cl, 5 dwg

Description

 The invention relates to a method for circulating cooling a container loaded with burnt fuel elements for transporting and / or storage of fuel elements. Tanks for transportation and / or storage, loaded with burnt fuel elements, usually experience more or less strong heating.

 Before further handling, these containers should first be cooled to low temperatures. In the framework of the invention, this cooling is called circulation cooling.

 A known method of circulating cooling a container, in which cooling water is introduced into the container from the water tank through the circulating cooling device, the water vapor generated in the container is continuously removed and condensed outside the container using cooling water from the water tank, and in the container using a gas supply the pump installation create a vacuum (DE 3129141 A, 03/17/83).

 In the initial phase, the vessels operate with overpressure. Due to the high vapor pressures arising, the connected circulating cooling device is subjected to very high thermal loads. Therefore, in the known devices, the circulation cooling system is very expensive and large in volume. In addition, with methods known from practice, the efficiency of heat removal from the tank leaves much to be desired. In order to achieve reasonable heat dissipation, expensive measures are also required. On the contrary, the invention is based on the technical task of proposing a method by which it is possible to quickly and efficiently cool containers using simple and inexpensive measures.

 The technical result is the creation of improved cooling efficiency and lower production costs.

 The technical result is achieved by the fact that the method of circulating cooling a container loaded with burnt out fuel elements for transporting and / or storing the fuel elements includes operations in which cooling water is introduced into the container from the water tank through the circulation cooling device, water vapor generated in the container is continuously removed and subjected to condensation outside the tank with the help of cooling water from the tank with water, and in the tank with the help of a gas pumping unit I create t rarefaction, while the vacuum is maintained during the entire process of circulation cooling during the removal of water vapor, and the water vapor condenses in the mixing condenser in countercurrent with respect to the cooling water. The pumping unit available, preferably for drying purposes, is used to create a vacuum and to divert water vapor. Condensed water vapor is again sent to the water tank and / or to the container.

It is advisable to use as a water reservoir a water basin for combustible (fuel) elements of the reactor and supply cooling water from this water basin to the tank through a circulation cooling device. Preferably, cooling water is introduced into the container at a temperature of approximately 40 ^° C. As cooling water, substantially degassed water is meant. It goes without saying, in the framework of the method according to the invention, circular cooling can be carried out simultaneously in several tanks and several tanks can be connected simultaneously to the circular cooling device and / or pump device. Therefore, paragraph 1 of the claims also covers a method of circular cooling of several containers with burnt fuel elements loaded into them.

 According to a preferred embodiment, which is of particular importance in the framework of the invention, a pumping device already existing for other purposes is used to create vacuum and water vapor removal. It is preferable to use an existing pumping device designed for drying containers to create a vacuum and the removal of water vapor. This refers, for example, to a pumping device that serves as a source of vacuum, which, as part of a filling installation for transporting and / or serving for storage of containers with radioactive waste, known from DE-PS 32 00 331, is used for drying or vacuum drying of radioactive waste.

 It is preferable to create a vacuum in the tank before and during the circulating cooling process. It is advisable to control or adjust the pressure in the tank, namely in such a way that the pressure in the tank during the entire cooling process is 1 bar. According to a preferred embodiment of the invention, the pressure and pressure of the vapor in the vessel is from 0.1 to 0.4 bar, preferably from 0.1 to 0.3 bar. It goes without saying that, in addition, the gases present or generated in the tank are vented using a pumping device.

 Water vapor discharged from the vessel is preferably condensed with cooling water from a water tank. According to a preferred embodiment of the invention, which is of particular importance in the framework of the invention, water vapor condenses in a mixing condenser. By mixing condenser is meant a device in which the water vapor to be condensed is uniformly mixed with cooling water. Preferably, the water vapor in the mixing condenser is directed in countercurrent with respect to the cooling water. Condensable water vapor, it is advisable to again bring in the water tank and / or in the tank. According to a preferred embodiment of the invention, steam condensed and mixed with cooling water is supplied as cooling water to a water tank and a container.

The invention is based on the fact that a particularly efficient and rapid cooling of a container loaded with fuel cells can be achieved if a vacuum is created in the container and water vapor arising from this in the container is simultaneously continuously pumped out. Due to this, in a relatively short time there is an effective heat removal with simultaneous direct removal of the heat of evaporation by creating a vacuum and due to this cooling of the tank. The cooling process takes place without significant slowdowns, first at the bottom of the tank and gradually, with a continuously increasing water level, captures all areas of the walls of the tank and objects in the tank. Between cooling water and surfaces to be cooled, significant temperature equalization occurs relatively quickly. The result is a very fast and efficient cooling of the tank with a relatively low cost. Compared with the prior art already described, an additional advantage is created in that the cooling tank does not have to be located in the water pool for the reactor fuel elements, and due to the effective cooling achieved in the framework of the invention, it can already be located in its own intended for this purpose location. A typical tank for transportation and / or storage, loaded with fuel elements with a maximum residual power of (nuclear) decay, can be cooled in approximately 10 hours by the method according to the invention to a temperature of 60 ^° C. After this, no additional circulation cooling measures are necessary. The invention is based, in particular, on the fact that, within the framework of the method according to the invention, an existing pumping device can be used, in particular for drying containers, to create a vacuum. This form of execution of the method is characterized by the simplicity of its implementation and low costs. With the help of an existing pumping device, it is possible, without expensive means for adaptation, to carry out the method according to the invention.

In the framework of the invention there are many possibilities for additional forms of implementation. It is advisable to control and regulate the cooling process according to the rate of supply of cooling water to the tank and / or regulation of the vacuum created by the pumping device. Below the invention is explained in more detail using only one example of execution shown in the drawings. Here is schematically shown:
FIG. 1 - a device for implementing the method according to the invention,
FIG. 2 - temperature of the various zones of the tank as a function of time for an example of execution, explained below,
FIG. 3 - temperature of the fuel elements as a function of time,
FIG. 4 - steam pressure in the tank as a function of time,
FIG. 5 - capacity filling level as a function of time.

 In FIG. 1 shows a device for implementing the method according to the invention for cooling a tank 1 loaded with burnt fuel elements for transporting and / or storage of fuel elements. Cooling water is continuously supplied to the tank 1 through the inlet pipe 4 from the water tank 2 through the circulation cooling device 3, which in the exemplary embodiment of FIG. 1 water basin for reactor fuel cells. Already before the introduction of cooling water by means of a gas pumping device 5 through the discharge pipe 6 and the connecting pipe 7, the tank 1 and the cooling device 3 are evacuated, so that the gases that are still in the tank are first pumped out. In the embodiment of FIG. 1, an existing pumping device 5, already used for drying the container 1, can be used. The pumping device 5 preferably has two spool pumps for creating a vacuum, not shown in the drawings. In the embodiment of FIG. 1, for the sake of simplicity of the image, only capacity 1 is shown. It goes without saying that several containers 1 can also be connected to the circulation cooling device 3 or the pump device 5, for example, located next to each other. The container or containers may be located in a place intended for servicing or further transporting the containers, and in contrast to the above-described known cooling measures, should not be installed in the water tank 2 or the water pool for combustible elements.

 During the introduction of cooling water through the supply pipe 4 into the tank 1, a vacuum is created using the pump device 5 in the tank 1 and the cooling device 3. In this case, water vapor generated in the heated container 1 is continuously discharged. It goes without saying that other gases generated in the tank 1 are simultaneously discharged. Water vapor is condensed by means of cooling water from the water tank 2 in the condenser 8, made in the form of a counter-current mixing condenser. In this case, the water vapor supplied through the discharge pipe 6 to the condenser 8 is supplied in countercurrent to the cooling water supplied to the condenser 8 through the cooling water pipe 9. Cooling water is supplied from the water reservoir 2 to the condenser 8 through the cooling water pump 10. The cooling water mixed with the condensing water vapor, after exiting the condenser 8 through the pump 11, is supplied by the first partial stream through the pipe 4 to the tank 1. The second partial stream of cooling water mixed with the condensing water vapor is returned to the water tank 2. During the cooling process capacity 1 is gradually filled with cooling water. The gases discharged from the tank 1 and the water vapor, possibly not condensed in the condenser 8, are discharged through the connecting pipe 7 by the pumping device 5 from the condenser 8. The gas mixture is passed through an additional condenser 12 to condense the water vapor still remaining in the gas mixture since the pumping device has, as a rule, only limited compatibility with steam. In the emission condenser 13, connected behind the pumping device 5, still existing steam condenses and the exhaust gases, possibly with the remaining steam, are led through the exhaust pipe 14 to the ventilation system. Below, the method according to the invention is explained in more detail using an example implementation.

Execution example
The method according to the invention is carried out using the device of FIG. 1 and explained above. A conventional tank was used to transport irradiated fuel elements having a maximum residual decay power of 21 kW. In the tank at a temperature of 40 ^o C was introduced cooling water in an amount of 20 l / min The ambient temperature was 27 ^o C. The free volume of the tank available for receiving cooling water was 4.4 m ³ . The free surface available for contact with cooling water was 1.32 m ² . In FIG. 2 shows the temperature characteristic during the cooling process over a period of time equal to 9 hours. Curve A, drawn by a solid line, shows the temperature characteristic on the primary lid of the tank, curve B, shown by the dashed line, shows the temperature on the wall of the tank, and curve C, shown by the dash-dot line, shows the temperature characteristic for the bottom of the tank for a specified period of time. It can be seen that, in about 10 hours, the vessel is cooled to a temperature of about 60 ^° C. FIG. Figure 3 shows the temperature characteristic of fuel cells for the first three hours of circulation cooling. In FIG. 4 shows the vapor pressure in the tank during the first three hours of cooling. The pressure was constantly maintained in the tank below 1 bar, i.e. a vacuum. The curve maximum according to FIG. 4 is just below 1 bar. At the appropriate time, the outlet pipe 6 of the tank was temporarily closed. In FIG. 5, the solid line shows the level of filling the tank with cooling water after 9 hours. As a result, a relatively quick and efficient cooling of the tank was achieved. Additional cooling measures were not required and the tank could be used for further manipulations or for further transportation.

Claims (3)

 1. A method for circulating cooling a container loaded with burnt out fuel elements for transporting and / or storing fuel elements, in which cooling water is introduced into the container from the water tank through the circulating cooling device, water vapor generated in the container is continuously removed and condensed outside the container using cooling water from the tank with water, and in the tank using a gas pumping unit create a vacuum, characterized in that the vacuum is maintained during the entire process of circulating the cooling water during retraction vapor and water vapor condenses in the mixing condenser in countercurrent to the cooling water.  2. The method according to claim 1, characterized in that already available, preferably for drying the tank, the pumping unit is used to create a vacuum and to remove water vapor.  3. The method according to claim 1 or 2, characterized in that the condensed water vapor is again sent to the water tank and / or to the tank.

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